CN114554068A - Optical anti-shake camera module - Google Patents

Abstract

The application relates to an optics anti-shake module of making a video recording, it includes: a lens; a photosensitive assembly; a first driving section; and a second drive portion having four sides, at least one side of the second drive portion having at least one SMA wire disposed thereon; each SMA wire is positioned in a gap between the second movable part and the second base part, the outer side surface of the second movable part is provided with an extension part, the extension part is in contact with the waist part of the SMA wire, and the extension part presses and bends the SMA wire along the x-axis direction or the y-axis direction at the waist part of the SMA wire under the action of the elasticity of the elastic connecting part; the second driving part enables the SMA wire to contract by electrifying the SMA wire so as to move the photosensitive chip in the direction of the x axis or the y axis; and the lens and the photosensitive chip are configured to be driven simultaneously and move in opposite directions. This application can improve the anti-shake stroke and the anti-shake response speed of the module of making a video recording with less volume cost.

Description

Optical anti-shake camera module

Technical Field

The invention relates to the technical field of camera equipment, in particular to an optical anti-shake camera module.

Background

Along with the increase of the demand of consumers for mobile phone photographing, the functions of a mobile phone camera (i.e. a camera module) are more and more abundant, the functions of portrait photographing, long-distance photographing, optical zooming, optical anti-shake and the like are integrated in the camera with a limited volume, and the functions of automatic focusing, optical anti-shake, optical zooming and the like are usually realized by depending on an optical actuator (sometimes also referred to as a motor).

Fig. 1 shows a typical camera module with a motor in the prior art. Referring to fig. 1, the camera module generally includes a lens 1, a motor mechanism 2 (which may be simply referred to as a motor), and a photosensitive member 3. In the shooting state of the camera module, light from a shooting object is focused on a photosensitive element 3a of a photosensitive assembly 3 through a lens 1. Structurally, the lens 1 is fixed to a motor carrier (specifically shown in fig. 1) of a motor, and the motor carrier is a movable component which can drive the lens 1 to move in the optical axis direction under the action of a driving element of the motor to realize a focusing function. For a camera module with an optical anti-shake (OIS) function, the motor usually has a more complicated structure. This is because the motor needs to drive the lens 1 to move in other degrees of freedom (e.g., in a direction perpendicular to the optical axis) in addition to the lens to move in the optical axis direction to compensate for a shake at the time of shooting. In general, the shake of the image pickup module includes translation in a direction perpendicular to the optical axis (translation in the x-axis and y-axis directions) and rotation (rotation in the xoy plane, whose rotation axis direction may be substantially the same as the optical axis), and tilt shake (rotation around the x-axis and y-axis, and tilt shake is also called tilt shake in the field of image pickup modules). When the gyroscope (or other position sensing element) in the module detects the shake in a certain direction, a command can be sent to make the motor drive the lens to move a distance in the opposite direction, so as to compensate the shake of the lens. Generally, the lens is only translated and/or rotated in a direction perpendicular to the optical axis to compensate the shake of the camera module, because if the lens is rotated around the x and y axes, i.e. if the anti-shake effect is achieved through tilt adjustment of the lens, the imaging quality of the module may be reduced, and even the basic imaging quality requirement may be difficult to achieve due to imaging blur.

However, as the imaging quality of the mobile phone camera module is higher and higher, the volume and weight of the lens are higher and higher, and the requirement for the driving force of the motor is also higher and higher. However, the current electronic devices (such as mobile phones) also have a great limitation on the size of the camera module, and the occupied size of the motor increases correspondingly with the increase of the lens. In other words, in the trend of the lens barrel toward larger volume and larger weight, the driving force provided by the motor is difficult to increase accordingly. On the premise that the driving force is limited, the heavier the lens is, the shorter the stroke of the motor capable of driving the lens to move is, and the anti-shake capability is affected. On the other hand, the heavier the lens, the slower the motor can drive the lens to move, and the longer the lens reaches the predetermined compensation position, which also affects the anti-shake effect.

Therefore, a solution capable of improving the anti-shake stroke and anti-shake response speed of the camera module is urgently needed.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide a solution capable of improving the anti-shake stroke and anti-shake response speed of a camera module.

In order to solve the above technical problem, the present invention provides an optical anti-shake camera module, which includes: a lens; a photosensitive assembly having a photosensitive chip; the first driving part is suitable for mounting the lens and driving the lens to translate in the direction of the x axis or the y axis; the photosensitive assembly is fixed on the second movable part, the second base part and the second movable part are movably connected through an elastic connecting part, the second driving part is provided with four side surfaces, and at least one SMA wire is arranged on at least one side surface of the second driving part; each SMA wire is positioned in a gap between the second movable part and the second base part, two ends of each SMA wire are respectively fixed and electrically connected to two fixed ends positioned on the second base part, and the two fixed ends are respectively positioned in two adjacent corner areas of the second base part; the outer side surface of the second movable part is provided with an extending part, the extending part is in contact with the waist part of the SMA wire, and the extending part presses and bends the SMA wire along the x-axis direction or the y-axis direction at the waist part of the SMA wire under the action of the elasticity of the elastic connecting part; the second driving part enables the SMA wire to contract by electrifying the SMA wire so as to move the photosensitive chip in the direction of the x axis or the y axis; the lens and the photosensitive chip are configured to be driven simultaneously and move towards opposite directions; the x axis and the y axis are coordinate axes perpendicular to the optical axis of the camera module, and the x axis and the y axis are perpendicular to each other.

Wherein the first driving part is suitable for driving the lens to translate in the directions of the x axis and the y axis; the SMA wires comprise an x-axis drive SMA wire and a y-axis drive SMA wire; at least one X-axis drive SMA wire is arranged on at least one side surface of the second drive part, which is perpendicular to the X-axis, and the second drive part enables the X-axis drive SMA wires to contract by introducing current to the X-axis drive SMA wires so as to move the second movable part in the X-axis direction and further drive the photosensitive chip to move in the X-axis direction; and at least one y-axis drive SMA wire is arranged on at least one side surface of the second drive part, which is perpendicular to the y-axis, and the second drive part enables the y-axis drive SMA wire to contract by supplying current to the y-axis drive SMA wire so as to move the second movable part in the y-axis direction, and further drive the photosensitive chip to move in the y-axis direction.

Wherein the extension is configured as a hook, a pulley, or an arcuate track.

Wherein the second base portion has four corner regions, three of which have the fixed ends, and the fixed end of one of the corner regions fixes both the x-axis drive SMA wire and the y-axis drive SMA wire.

Wherein the second driving portion has a first side, a second side intersecting the first side, a third side opposite the first side, and a fourth side opposite the second side; the x-axis drive SMA wires are disposed only on the first side and the y-axis drive SMA wires are disposed only on the second side.

Wherein, the second driving part is only provided with one X-axis driving SMA wire and one y-axis driving SMA wire.

Wherein in the second driving portion, a gap between the second base portion inner side surface and the second movable portion outer side surface on the first side is larger than a gap between the second base portion inner side surface and the second movable portion outer side surface on the third side; the gap between the second base portion inner surface and the second movable portion outer surface on the second side is larger than the gap between the second base portion inner surface and the second movable portion outer surface on the fourth side.

The photosensitive assembly further comprises a circuit board and an electronic element mounted on the surface of the circuit board, the photosensitive chip is mounted in the central area of the circuit board, the electronic element is located on the outer side of the photosensitive chip, and the electronic element is located on the first side and/or the second side.

In the photosensitive assembly, the circuit board has four edge regions, namely a first edge region located on the first side, a second edge region located on the second side, a third edge region located on the third side, and a fourth edge region located on the fourth side; the width of the third edge region is less than the width of the first edge region; the width of the fourth edge region is less than the width of the first edge region; and the width of the edge area is the distance from the edge of the photosensitive chip to the edge of the circuit board.

Wherein the extension is at a different height than the fixed end, the height being a position in a z-axis direction, the z-axis being a coordinate axis perpendicular to the x-axis and the y-axis.

Wherein the first driving part includes a first base part and a first movable part, and the second base part is fixed to the first base part.

Wherein the first base portion is located at a periphery of the first movable portion; the second basic portion includes basic portion lateral wall and base, the bottom surface of basic portion lateral wall with the base is connected, the top surface of basic portion lateral wall with first basic portion is connected.

The edge area of the bottom surface of the first base part forms a step-shaped notch, and the side wall of the base part can extend upwards and extend into the step-shaped notch and is connected with the first base part.

The second movable part comprises a movable part main body which is flat and provided with a light through hole in the center; the outer edge area of the bottom surface of the movable part main body extends downwards to form a movable part side wall.

The photosensitive assembly comprises the photosensitive chip, a circuit board, a lens base and an optical filter; the photosensitive chip is arranged on the upper surface of the circuit board, the lens base is arranged on the upper surface of the circuit board and surrounds the photosensitive chip, and the optical filter is arranged on the lens base; the bottom surface of the side wall of the movable part is bonded with the upper surface of the circuit board of the photosensitive assembly; an accommodating cavity is formed among the inner side surface of the side wall of the movable part, the bottom surface of the main body of the movable part, the upper surface of the circuit board and the outer side surface of the mirror base, and electronic elements are arranged in the accommodating cavity; the second driving part has a first side, a second side intersecting the first side, a third side opposite to the first side, and a fourth side opposite to the second side; the x-axis drive SMA wires are disposed only on the first side and the y-axis drive SMA wires are disposed only on the second side; the electronic components are located on the first side and/or the second side.

The edge area of the inner side of the movable part main body is provided with a step-shaped notch facing to the object side so as to avoid the optical lens.

Wherein the second base part is fixed to the first drive part, the second base part including a base part side wall that surrounds the second movable part, a gap for accommodating the SMA wire being provided between the base part side wall and the second movable part.

The photosensitive assembly comprises a suspension type circuit board, the suspension type circuit board comprises a rigid circuit board main body and a flexible connecting band, the connecting band is led out from a first side face and a second side face of the circuit board main body and is bent upwards to form a bent portion, the top of the bent portion extends along the periphery of the photosensitive assembly in the horizontal direction, so that the connecting band surrounds the peripheries of the first side face, the second side face and a third side face of the photosensitive assembly, the connecting bands positioned on the first side face and the second side face are respectively provided with at least one suspension part, and the suspension parts are fixed on a second base part of the second driving part or fixed with the second base part through an intermediary; the photosensitive assembly is provided with a first side face and a second side face, the positions of the first side face and the second side face are consistent with those of the circuit board main body, the first side face and the second side face are oppositely arranged, and the third side face intersects with the first side face and the second side face.

Wherein the suspension part is provided with a suspension hole, and the second base part or the intermediate object is provided with a hook which hooks the suspension hole.

And a part of the section of the connecting band is attached with a rigid substrate for reinforcement so as to form the suspension part.

The suspension type circuit board is made of a rigid-flex board, the circuit board main body and the suspension parts are formed by rigid board parts of the rigid-flex board, and the bending parts and connecting belt sections connected among the suspension parts are formed by flexible board parts of the rigid-flex board.

The connecting band comprises a third connecting band and a fourth connecting band, the third connecting band is led out from the first side face of the circuit board main body and is bent upwards to form a bent part, then the third connecting band extends along the first side face of the photosensitive assembly, and the third connecting band is bent in the horizontal direction at a corner and continues to extend along the third side face; the fourth connecting band is led out from the second side face of the circuit board main body and is bent upwards to form another bent part, then extends along the second side face of the photosensitive assembly, is horizontally bent at a corner and continues to extend along the third side face; the third connecting band and the fourth connecting band are joined at the third side surface and conducted to each other.

The camera module further comprises a first connecting belt electrically connected with the first driving part, and the first connecting belt is led out from the top area of the first driving part, is bent downwards, is connected with the third connecting belt or the fourth connecting belt on the third side surface and is conducted.

The camera module further comprises an outer shell, wherein the inner side surface of the outer shell is provided with a containing groove used for containing the joint part of the third side surface; wherein the joint portion is a joint portion where the first connecting band, the third connecting band, and the fourth connecting band are joined to each other; and glue is poured into the accommodating groove to fix the first connecting belt, the third connecting belt and the fourth connecting belt to the shell.

The connecting belt positioned on the third side is further connected with a fifth connecting belt, and the fifth connecting belt is provided with a connector for external connection; the suspension type circuit board is also provided with a fixing part for fixing the fifth connecting band.

The camera module further comprises an outer shell, wherein the inner side surface of the outer shell is provided with a containing groove used for containing the joint part of the third side surface; wherein the joint portion is a joint portion where the first connecting band, the third connecting band, and the fourth connecting band are joined to each other; and glue is poured into the accommodating groove to fix the first connecting belt, the third connecting belt and the fourth connecting belt to the shell.

Determining a lens moving distance b for driving the lens to move by the first driving module and a photosensitive chip moving distance c for driving the photosensitive chip to move by the second driving module according to the detected inclined shaking angle a of the camera module; the lens moving distance b, the photosensitive chip moving distance c and the image space focal length f of the camera module meet the following requirements: a is arctan (b/f) + arctan (c/f).

The driving structure further comprises a driving logic module, wherein the driving logic module is used for keeping the proportion of the lens moving distance b to the photosensitive chip moving distance c at a preset fixed proportion.

The driving structure further comprises a driving logic module which is provided with an anti-shake threshold K, the driving logic module is used for keeping the proportion of the lens moving distance b to the photosensitive chip moving distance c at a preset fixed proportion when the inclined shake angle a is smaller than or equal to the anti-shake threshold K, and the photosensitive chip moving distance c reaches the maximum value c of the moving stroke when the inclined shake angle a is larger than the anti-shake threshold K_maxThe lens moving distance b is in accordance with the relation b ═ tan (a/f) -c_maxAnd (6) calculating.

The preset fixed proportion of the moving distance of the lens and the moving distance of the photosensitive chip is set according to the weight of the lens, the driving force of the first driving part, the weight of the photosensitive chip or the photosensitive assembly and the driving force of the second driving part, so that the time for moving the lens and the photosensitive chip to the respective anti-shake target positions is consistent.

Compared with the prior art, the application has at least one of the following technical effects:

1. this application can improve the anti-shake stroke of the module of making a video recording to can compensate the great shake of the module of making a video recording.

2. This application can improve the anti-shake response speed of the module of making a video recording.

3. The utility model provides an optics anti-shake module of making a video recording has compact structure's advantage, is particularly suitable for miniaturized module of making a video recording.

4. In some embodiments of the present application, the setting may be performed according to the weight of the lens, the weight of the driving force of the first driving portion, the weight of the photosensitive chip (or the photosensitive assembly), the driving force of the second driving portion, and other factors, so that the time for the lens and the photosensitive chip to move to the respective anti-shake target positions is substantially the same, thereby obtaining a better anti-shake effect.

5. In some embodiments of this application, through SMA line drive photosensitive assembly removal, can improve the anti-shake stroke and the anti-shake response speed of making a video recording the module with less volume cost.

6. In some embodiments of the present application, the circuit board and the second driving portion may adopt an asymmetric design, and the size of one or more sides (e.g., the third side and the fourth side) of the photosensitive assembly and the second driving portion is reduced by concentrating the SMA wires on the first side and/or the second side and concentrating the electronic elements on the edge area of the circuit board of the first side and/or the second side, so as to improve the anti-shake stroke and the anti-shake response speed of the camera module at a smaller volume cost.

Drawings

FIG. 1 illustrates a typical camera module having a motor in the prior art;

fig. 2 is a schematic cross-sectional view illustrating a camera module with an anti-shake function according to an embodiment of the present application;

fig. 3 is a schematic cross-sectional view illustrating a camera module with an anti-shake function according to another embodiment of the present application;

FIG. 4 is a schematic diagram illustrating the relationship between the moving distance of the lens and the photosensitive chip and the inclination angle of the module under four different conditions in the present application;

fig. 5 is a schematic cross-sectional view illustrating a camera module according to an embodiment of the present application;

fig. 6 is a schematic cross-sectional view illustrating a camera module according to another embodiment of the present disclosure;

fig. 7 shows a schematic cross-sectional view of a camera module in a further embodiment of the present application;

fig. 8 is a schematic cross-sectional view illustrating a camera module according to still another embodiment of the present application;

fig. 9a is a schematic cut-away perspective view of a camera module in an embodiment of the present application;

fig. 9b shows a schematic cross-sectional view of a camera module in an embodiment of the present application;

FIG. 10 illustrates a schematic top view of a second drive section in one embodiment of the present application;

fig. 11 is a schematic cross-sectional view of a camera module according to an embodiment of the present application;

fig. 12 is a schematic cross-sectional view of the camera module of fig. 11 after marking a part of the edge area of the circuit board;

FIG. 13 illustrates an assembled perspective view of the second driving portion and the photosensitive assembly in one embodiment of the present application;

FIG. 14 illustrates an exploded view of a second drive portion and a photosensitive assembly in one embodiment of the present application;

FIG. 15 is a perspective view of a photosensitive assembly and a suspension board used therein according to an embodiment of the present application;

fig. 16a shows a schematic front view of a suspended wiring board in an embodiment of the present application after deployment;

fig. 16b shows a schematic back view of a suspension board in an embodiment of the present application after deployment;

fig. 17a shows a schematic front view of a suspension board according to another embodiment of the present application after deployment;

fig. 17b shows a schematic back view of a suspension board in an embodiment of the present application after deployment;

fig. 18 is a schematic perspective exploded view of a suspension board based camera module according to an embodiment of the present application;

fig. 19 illustrates a perspective view of a suspension circuit board based camera module with a housing according to one embodiment of the present application.

Detailed Description

For a better understanding of the present application, various aspects of the present application will be described in more detail with reference to the accompanying drawings. It should be understood that the detailed description is merely illustrative of exemplary embodiments of the present application and does not limit the scope of the present application in any way. Like reference numerals refer to like elements throughout the specification. The expression "and/or" includes any and all combinations of one or more of the associated listed items.

It should be noted that the expressions first, second, etc. in this specification are used only to distinguish one feature from another feature, and do not indicate any limitation on the features. Thus, a first body discussed below may also be referred to as a second body without departing from the teachings of the present application.

In the drawings, the thickness, size, and shape of an object have been slightly exaggerated for convenience of explanation. The figures are purely diagrammatic and not drawn to scale.

It will be further understood that the terms "comprises," "comprising," "includes," "including," "has," "including," and/or "including," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. Moreover, when a statement such as "at least one of" appears after a list of listed features, the entirety of the listed features is modified rather than modifying individual elements in the list. Furthermore, when describing embodiments of the present application, the use of "may" mean "one or more embodiments of the present application. Also, the term "exemplary" is intended to refer to an example or illustration.

As used herein, the terms "substantially," "about," and the like are used as terms of table approximation and not as terms of table degree, and are intended to account for inherent deviations in measured or calculated values that will be recognized by those of ordinary skill in the art.

Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

The invention is further described below with reference to the accompanying drawings and specific embodiments.

Fig. 2 is a schematic cross-sectional view illustrating a camera module with an anti-shake function according to an embodiment of the present application. Referring to fig. 2, in the present embodiment, the image capturing module includes a lens 10, a photosensitive assembly 20, a first driving portion 30, and a second driving portion 40. Wherein the photosensitive assembly 20 includes a photosensitive chip 21. The first driving part 30 is configured to drive the lens 10 to move in both x and y directions, and the second driving part 40 is configured to drive the photosensitive chip 21 to move in both x and y directions. In this embodiment, the x and y directions are perpendicular to each other and are parallel to the light-sensing surface of the light-sensing element 20. The z direction is parallel to the normal direction of the light-sensing surface. For the sake of understanding, fig. 2 also shows a three-dimensional rectangular coordinate system constructed based on x, y, and z directions. In this embodiment, the control module drives the lens 10 and the photosensitive chip 21 to move in opposite directions at the same time, so as to achieve optical anti-shake of the camera module. Specifically, the lens 1 and the photosensitive chip 21 are configured to be driven simultaneously and move in opposite directions, for example, when the lens 10 is driven to move in the positive x-axis direction, the photosensitive chip 21 is driven to move in the negative x-axis direction; when the lens 10 is driven to move towards the positive y-axis direction, the photosensitive chip 21 is driven to move towards the negative y-axis direction; alternatively, the lens 10 is driven to move in the x-axis and the y-axis, and the photosensitive chip 21 is driven to move in the x-axis and the y-axis in the opposite direction to the movement of the lens 10, in other words, when the movement in the x-axis and the y-axis is required, the directions of the displacement vector of the lens 10 and the displacement vector of the photosensitive chip 21 are opposite on the xoy plane. The camera module generally includes a position sensor for detecting shake of the camera module or a terminal device (i.e., an electronic device, such as a mobile phone, on which the camera module is mounted). When the shake is detected, the position sensor sends a signal to the camera module to drive the lens 10 and the photosensitive chip 21 to move correspondingly to compensate the shake, so that the purpose of optical anti-shake is achieved. In this embodiment, the lens 10 and the photosensitive chip 21 are configured to move simultaneously, and the moving directions of the lens 10 and the photosensitive chip 21 are opposite, so that a faster response can be realized, and a better anti-shake effect is achieved. In addition, the anti-shake angle range of the camera module is usually limited by the suspension system and the driving system, and a relatively large compensation angle range cannot be achieved. In addition, in the present embodiment, by driving the lens 10 or the photosensitive chip 21 to move in opposite directions at the same time, compared with a scheme of driving only the lens 10 to move, a stroke of the relative movement between the lens 10 and the photosensitive chip 21 is larger (for convenience of description, the stroke of the relative movement may be referred to as an anti-shake stroke), and a better compensation effect may be achieved. Particularly, due to the increase of the anti-shake stroke, the embodiment also has a good compensation effect on the tilt shake of the camera module. Further, the moving direction of the anti-shake movement of the embodiment can be defined in the xoy plane, and the optical axis of the lens 10 or the photosensitive chip 21 does not need to be inclined, so that the image blurring problem caused by the anti-shake movement is avoided.

Further, in another embodiment of the present application, the photosensitive chip 21 can also be driven by the second driving portion 40 to rotate in the xoy plane, so as to compensate for the shake in the rotation direction of the image capturing module.

Further, still referring to fig. 2, in an embodiment of the present application, the image pickup module includes a first driving part 30, a lens 10, a second driving part 40, and a photosensitive assembly 20. The lens 10 is mounted on the first driving part 30. The first driving unit 30 may have a cylindrical first motor carrier, which may be a movable portion of the first driving unit, and the lens may be mounted on an inner side surface of the first motor carrier. The first driving part is also provided with a static part or a basic part. In this embodiment, the base portion may be implemented as a motor housing. The motor housing may include a base and a cover. The base is provided with a light through hole. The movable part is movably connected with the base part. The drive element may be a coil magnet combination, which may be mounted between the movable part and the base part. For example between the first motor carrier and the motor housing. In fact, the first driving part in the present embodiment may directly adopt the common structure of the optical anti-shake motor in the prior art. Further, in the present embodiment, the second driving portion 40 may be supported and fixed on the bottom surface of the first driving portion 30. The second driving unit 40 may include a base unit and a movable unit. Wherein the base portion is directly connected with the first driving portion. The movable part is positioned below the base part and movably connected with the base part. The photosensitive assembly 20 includes a circuit board 23, a photosensitive chip 21 mounted on a surface of the circuit board, and a lens holder 22 surrounding the photosensitive chip 21. The base of the mirror base 22 may be attached to the surface of the circuit board 23, and the top surface thereof may be fixed to the movable portion of the second driving portion 40. The lens holder 22 has a light-passing hole at the center, and a filter 24 is mounted on the lens holder 22 (the filter 24 can also be regarded as a component of the photosensitive assembly 20). Under the driving of the movable portion of the second driving portion 40, the photosensitive assembly 20 can translate in the x and y directions or rotate on the xoy plane with respect to the base portion. For convenience of description, the base portion of the first driving portion 30 is sometimes referred to as a first base portion, the base portion of the second driving portion 40 is sometimes referred to as a second base portion, the movable portion of the first driving portion 30 is sometimes referred to as a first movable portion, and the movable portion of the second driving portion 40 is sometimes referred to as a second movable portion.

Fig. 3 is a schematic cross-sectional view illustrating a camera module with an anti-shake function according to another embodiment of the present application. In this embodiment, the image capturing module includes a first driving portion 30, a lens 10, a second driving portion 40, and a photosensitive assembly 20. The lens 10 is mounted on the first driving unit 30. The structure and assembly of the first driving part 30 and the lens 10 may be the same as those of the previous embodiment shown in fig. 2, and are not described again. The present embodiment differs from the previous embodiment in that: the second driving portion 40 is located inside the photosensitive assembly 20. In this embodiment, the photosensitive assembly 20 includes a circuit board 23, a lens holder 22, a filter 24, and a photosensitive chip 21. The base of the lens holder 22 may be mounted on the surface of the circuit board 23, and the top surface thereof may be fixed to the base of the first driving unit 30. The lens holder 22 has a light-passing hole at the center thereof, and a filter 24 is mounted on the lens holder 22. The lens holder 22, the filter 24 and the circuit board 23 may form a cavity, and the photosensitive chip 21 is located in the cavity 25. In this embodiment, the second driving portion 40 may be located in the cavity 25. Specifically, the base portion of the second driving portion 40 may be mounted on the surface of the circuit board 23, and the movable portion of the second driving portion 40 may be movably connected to the base portion. The photosensitive chip 21 is mounted on the surface of the movable portion. In this way, the photosensitive chip 21 can be translated in the x and y directions or rotated on the xoy plane with respect to the base portion by the movable portion of the second driving portion 40.

Different structural implementations of the second driving part of the camera module according to the present application are described above with reference to two embodiments. The following further introduces a method for compensating the tilt jitter of the camera module based on the design idea of the present application.

Fig. 4 is a schematic diagram illustrating the relationship between the moving distance of the lens and the photosensitive chip and the inclination angle of the module under four different conditions in the present application. The position A in the figure represents the moving distance combination of the lens and the photosensitive chip for compensating the shake angle a of the camera module. As shown in fig. 4, the lens moving distance is b, the photosensitive chip (hereinafter sometimes simply referred to as chip) moving distance is c, and the lens or chip moving distance may be equivalent to an angle of an image plane from an optical axis in optical imaging. Specifically, when the lens is translated by a distance b in the xoy plane, the image plane offset angle α 1 is caused to have an arithmetic relationship with an image distance, which is different at different shooting distances, and the image distance is replaced by an image space focal distance for calculation and convenience of description. Specifically, it causes the relationship between the image plane offset angle α 1 and the lens image space focal length f to be: tan (α 1) ═ b/f, which causes the relationship between the image plane shift angle α 2 and the lens image space focal length f when the photosensitive chip is translated by a distance c in the xoy plane, to be: tan (α 2) ═ c/f. In this embodiment, the moving directions of the lens and the photosensitive chip are opposite, so the calculation mode of the comprehensive compensation angle a of the camera module is as follows: α 1+ α 2 is arctan (b/f) + arctan (c/f). In one embodiment, the moving distance of the lens and the photosensitive chip may be set to be the same, i.e., b ═ c. In another embodiment, the distance that the lens and the photosensitive chip move may be set to be unequal, for example, the distance that the lens moves may be greater than the distance that the photosensitive chip moves, i.e., b > c. In this embodiment, the second driving portion may select a smaller-sized driver (such as a mems driver, etc., and the movable stroke of such a driver is usually relatively small), so as to help achieve miniaturization of the camera module as a whole.

Further, in an embodiment of the present application, a ratio between a lens moving distance and a photo sensor moving distance is optionally set to maintain a fixed ratio, for example, b/c is 6:4, or b/c is 7:3, or b/c is 5:5, and the moving distances of the lens and the photo sensor maintain the preset ratio no matter what compensation value (for example, the comprehensive compensation angle a) of the camera module shake, which is beneficial to uniformity of compensation effect of the camera module in a compensation range and also beneficial to reduction of design difficulty of the camera module anti-shake system driving logic module.

Further, in a configuration in which the lens movement distance and the photosensitive chip movement distance are subjected to anti-shake movement based on a fixed ratio, since the movable range of the photosensitive chip is small, shake of the image pickup module may exceed the maximum movement stroke of the photosensitive chip sometimes. Therefore, in an embodiment of the present application, an anti-shake threshold may be set, for example, a threshold K may be set for a shake angle a that needs to be compensated, and when the actually calculated shake angle a is smaller than or equal to the anti-shake threshold K, the lens moving distance b and the photosensitive chip moving distance c are maintained at a fixed ratio, which may be set in advance, for example, b/c is 6:4, b/c is 7:3, or b/c is 5: 5. When the actually calculated shaking angle a is larger than the anti-shaking threshold K, the moving distance c of the photosensitive chip is the maximum value of the moving stroke, namely the maximum stroke c of the photosensitive chip_maxAnd the lens moving distance b equals tan (a/f) -c_max. In other words, when the shake angle of the camera module to be compensated is above the anti-shake threshold K, the lens moves to the maximum value corresponding to the moving distance of the photosensitive chip (i.e. the maximum stroke c of the photosensitive chip) based on the preset fixed proportion_max) After the position of (a), the first driving unit may drive the lens to move continuously until the lens moving distance b is tan (a/f) -c_max. At the same time, the photosensitive chip is firstly synchronously moved to the maximum value c of the moving distance of the photosensitive chip in the opposite direction_maxAnd then remain stationary.

Further, in another aspect of the present applicationIn one embodiment, the maximum stroke b of the lens movement is in the xoy plane_maxThe corresponding anti-shake angle (the anti-shake angle refers to the angle of the camera module inclined shake) can be smaller than the maximum stroke c of the photosensitive chip_maxThe corresponding anti-shake angle. Under this kind of design, the anti-shake system of the module of making a video recording can have faster response speed. In a high-end lens, the lens often has more lenses, for example, the number of lenses in a rear main shooting lens in a current smart phone can reach 8, in order to further improve the imaging quality, some lenses also use glass lenses, which all result in larger lens weight. When the driving force is not increased significantly, the speed at which the driving device drives the lens to move will decrease. And the weight of the photosensitive chip or the photosensitive assembly is relatively light, and the photosensitive chip or the photosensitive assembly can reach the preset position with small driving force. Therefore, in the scheme of the embodiment, the advantages that the weight of the photosensitive chip or the photosensitive assembly is relatively close and the moving speed is relatively high can be better utilized, and the response speed of the camera module anti-shake system is effectively improved.

Further, in another embodiment of the present application, the fixed ratio of the moving distance of the lens to the moving distance of the photosensitive chip may be set according to the weight of the lens, the driving force of the first driving portion, the weight of the photosensitive chip (or the photosensitive assembly), the driving force of the second driving portion, and other factors, and a suitable fixed ratio is set, so that the time for the lens and the photosensitive chip to move to the respective anti-shake target positions is substantially the same, thereby obtaining a better anti-shake effect. Specifically, the weight of the lens and the driving force of the first driving portion may substantially determine the moving speed of the lens, and the weight of the photosensitive chip (or the photosensitive assembly) and the driving force of the second driving portion may substantially determine the moving speed of the photosensitive chip, and when the moving speed of the lens is smaller than the moving speed of the photosensitive chip (for example, when the weight of the lens is large), the moving distance of the photosensitive chip may occupy a larger proportion when the fixed proportion is set, so that the characteristic that the moving speed of the photosensitive chip is fast can be utilized, so that the photosensitive chip moves a longer distance, and the time for moving the lens and the photosensitive chip to the respective anti-shake target positions is substantially the same.

Further, in another embodiment of the present application, the first driving portion may employ a driving element having a large driving force, and a suspension system having a large stroke. For example, the first drive portion may be driven using an SMA (shape memory alloy) element. Compare traditional coil magnet combination, the SMA component can provide great drive power with less occupation space, consequently first drive division can design compacter, is favorable to making a video recording the miniaturization of module.

Further, fig. 5 shows a schematic cross-sectional view of a camera module in an embodiment of the present application. Referring to fig. 5, in the present embodiment, the base portion 41 of the second driving portion 40 is fixed with the base portion (not specifically shown in fig. 5) of the first driving portion 30. The lens 10 may be mounted to a movable portion (e.g., a first motor carrier, not specifically shown in fig. 5) of the first driving portion 30. The photosensitive assembly 20 includes a circuit board 23, a photosensitive chip 21, a lens holder 22, an optical filter 24, and the like. The photosensitive member 20 may be mounted to the movable portion 42 of the second driving portion 40. Specifically, the bottom surface of the moving portion 42 may bear against the top surface of the mirror base 22 of the photosensitive assembly 20. In the second driving portion 40, the base portion 41 and the movable portion 42 may be elastically connected by a suspension system. In this embodiment, the suspension system allows the movable part 42 to translate in the xoy plane relative to the base part 41. Alternatively, the suspension system may be a ball system, which has the advantages of: in the z direction, the movable part 42 and the base part 41 are in contact with each other through the balls, the movable part 42 moves only in the xoy plane, and the movement in the optical axis direction can be prevented by the balls between the movable part 42 and the base part 41, thereby avoiding the influence on the focusing of the image pickup module.

Alternatively, in another embodiment, the suspension system may comprise an elastic element (e.g., a spring) by which the fixed part and the movable part are connected, which allows the movable part to translate relative to the base part in the xoy plane, but prevents the movable part from moving relative to the base part outside the xoy plane. Compared with a ball system, the elastic element has the advantages that: the elastic element can provide an initial force between the base part and the movable part, the initial force can control the moving distance of the movable part or keep the position of the movable part in cooperation with the driving force of the driving element, and the driving element is not required to be additionally arranged to provide a conjugate driving force to control the position of the movable part. If a ball system is used, the movable part is free to move in the xoy direction relative to the base part in the case of a drive element which does not provide a driving force, so that it is often necessary to provide at least one pair of mutually opposite driving forces to control the holding of the movable part in its initial position.

Further, still referring to fig. 5, in one embodiment of the present application, anti-shake may be achieved by driving the entire photosensitive assembly 20 to move. Simultaneously, circuit board 23, sensitization chip 21, microscope base 22, light filter 24 encapsulation are as an organic whole, and circuit board 23, microscope base 22, light filter 24 form an enclosure space, and sensitization chip 21 holds in this enclosure space, has promoted sensitization subassembly 20's closure, has guaranteed that sensitization chip 21 images and does not receive the influence of dust in the module preparation of making a video recording or use.

In this embodiment, still referring to fig. 5, in an embodiment of the present application, the back surface of the circuit board may directly abut against a terminal device (i.e., an electronic device carrying the camera module, such as a mobile phone), and specifically, the back surface of the circuit board 23 may abut against a main board or other abutting member 90 of the terminal device. Although the movable portion 42 is connected to the photosensitive assembly 20 and the base portion 41 is connected to the first driving portion 30 in the present embodiment, it is understood that the movable portion 42 and the base portion 41 move relatively. In the anti-shake movement, the opposite movement direction means: the moving direction of the movable part of the first driving part relative to the base part is opposite to the moving direction of the movable part of the second driving part relative to the base part.

Further, fig. 6 shows a schematic cross-sectional view of a camera module according to another embodiment of the present application. Referring to fig. 6, in the present embodiment, a rear case 49 is added below the second driving portion 40, the rear case 49 is connected to the base portion 41 of the second driving portion 40, and forms an accommodating cavity, and the movable portion 42 of the second driving portion 40 and the photosensitive assembly 20 are accommodated in the accommodating cavity. As shown in fig. 6, there may be a gap 49a between the photosensitive assembly 20 and the bottom of the rear housing 49. That is, the photosensitive assembly 20 is suspended, and the photosensitive assembly 20 is connected only to the movable portion 42 of the second driving portion 40. In this embodiment, the rear housing 49 directly bears against the terminal device. Since the rear case 49 connects the terminal device, the second driving unit 40, and the base of the first driving unit 30, the movable portions of the first driving unit 30 and the second driving unit 40 respectively drive the lens 10 and the photosensitive assembly 20 to move in opposite directions simultaneously with respect to the terminal device during the anti-shake process. Further, in the present embodiment, the movable portion 42 of the second driving portion 40 is directly bonded to the upper end surface of the photosensitive assembly 20, so that the filter 24 can be spaced from the external space, and debris generated by friction or collision of the movable portion 42 during movement relative to the base portion 41 is prevented from directly falling onto the surface of the filter 24.

Fig. 7 shows a schematic cross-sectional view of a camera module in a further embodiment of the present application. Referring to fig. 7, in the present embodiment, the first driving part 30 is implemented to be adapted to drive the lens 10 to move in the optical axis direction to implement a focusing function, while also being adapted to drive the lens 10 to move in the xoy plane to implement an anti-shake function. Optionally, the first driving part 30 includes at least two carriers, namely a first carrier 31 and a second carrier 32, the lens 10 is supported by the first carrier 31, a suspension system is disposed between the first carrier 31 and the second carrier 32, and a suspension system is disposed between the second carrier 32 and the housing 33 of the first driving part 30. In this embodiment, the suspension system between the first carrier 31 and the second carrier 32 (i.e. the first suspension system) is configured as a ball bearing system, and the suspension system between the second carrier 32 and the housing 33 (i.e. the second suspension system) is a suspension system based on elastic elements (e.g. spring plates). In the present embodiment, the second suspension system is provided outside the first suspension system, the first suspension system allowing the lens 10 and the first carrier 31 to translate in the xoy plane to realize the anti-shake function, and the second suspension system allowing the lens 10, the first carrier 31, and the second carrier 32 to integrally move in the optical axis direction to realize the focusing function. Alternatively, in another embodiment, the second suspension system may also be arranged inside the first suspension system. In another modified embodiment, the second suspension system may also be disposed below the first suspension system. In this embodiment, the suspension system refers to a system in which two members are movably connected and the degree of freedom of relative movement (i.e., the moving direction) of the two members is limited. These two articulatable parts may be referred to as a base part and a movable part, respectively. Typically, the suspension system is used in conjunction with a drive element (e.g., an SMA element or a coil magnet combination). Wherein a driving force is provided by the driving element, under which driving force the movable part is moved relative to the base part in a movement direction defined by the suspension system.

Further, fig. 8 shows a schematic cross-sectional view of a camera module in still another embodiment of the present application. Referring to fig. 8, the movable portion of the second driving portion 40 of the present embodiment may be provided with a downward extending extension arm 42a, and the extension arm 42a is adhered to the circuit board 23 of the photosensitive assembly 20. The extension arm 42a may be provided with an FPC board 42b, and the FPC board 42b may be directly soldered to the wiring board 23, thereby electrically connecting the driving element mounted on the movable portion to the wiring board 23. This embodiment can prevent the glue from flowing onto the filter when the photosensitive assembly 20 is bonded to the movable portion, thereby affecting the image formation. In addition, in the embodiment, a gap is formed between the upper end surface (i.e., the top end) of the photosensitive assembly 20 and the second driving portion 40, so that the color filter can be prevented from being scratched or broken.

Fig. 9a is a schematic cut-away perspective view of a camera module according to an embodiment of the present application. Referring to fig. 9a, in the present embodiment, the first driving portion has a receiving hole 30a at the center thereof, which is adapted to the outer side surface of the optical lens 10, so that the optical lens 10 is mounted in the receiving hole 30 a. The second driving part 40 is located below the first driving part 30. The second driving portion 40 includes a second base portion 41 and a second movable portion 42. In the present embodiment, the second base portion 41 may be a ring-shaped frame structure. Specifically, the frame structure may be formed of an annular base portion side wall 41a, and the base portion side wall 41a may surround the second movable portion 42. The top surface of the base portion sidewall 41a may be bonded to the first driving portion 30 by a second adhesive material 23b to fix the second driving portion 40 and the first driving portion 30 together. Note that fig. 9a shows only the overall shape of the first driving portion 30, and does not show the first base portion and the first movable portion separately. Generally, the first base portion is located at the periphery of the first movable portion. In this embodiment, the edge area of the bottom surface of the first driving portion (i.e., the edge area of the bottom surface of the first base portion) may form a step-shaped notch 33, and the base portion sidewall 41a of the second base portion 41 may extend upward and into the step-shaped notch 33. This design can enhance the structural strength of the second base portion 41 to more reliably mount the SMA wire and the second movable portion 42 and the photosensitive assembly 20 from which it is suspended. Further, this design also improves the rigidity of the connection of the second base portion 41 and the first driving portion 30, so that the movement of the second movable portion 42 is more stable and more accurate. Further, fig. 9b shows a schematic cross-sectional view of a camera module in an embodiment of the present application. Referring to fig. 9a and 9b in combination, in the present embodiment, the bottom surface of the second movable portion 42 may be bonded to the circuit board 23 of the photosensitive assembly 20 by the first rubber material 23a, so as to fix the photosensitive assembly 20 and the second movable portion 42 together. The outer side of the second movable part 42 and the inner side of the second base part 41 (i.e. the inner side of the base part side wall 41 a) have a gap which can accommodate the SMA wire 48 and the spring 47 supporting the second movable part. Specifically, the second base portion 41 and the second movable portion 42 may be movably connected by a spring piece 47 (the spring piece may be replaced by another elastic connection portion). And the SMA wire may also be connected between the second base part 41 and the second movable part 42 and provide a driving force for the movement of the second movable part 42.

Further, still referring to fig. 9b, in an embodiment of the present application, the second movable portion 42 may include a movable portion main body 42a, and the movable portion main body 42a has a substantially flat plate shape and a through hole (i.e., a light passing hole) at the center thereof so as to pass light for image formation. An outer edge region of the bottom surface of the movable portion main body 42a extends downward to form a movable portion side wall 42b, and the bottom surface of the movable portion side wall 42b is bonded to the upper surface of the wiring board 23. A housing cavity is formed between the inner side surface of the movable portion side wall 42b, the bottom surface of the movable portion main body 42a, the upper surface of the circuit board 23, and the outer side surface of the mirror base 22, and can be used for disposing the electronic component 29. The electronic component 29 includes a resistor, a capacitor, and the like. These electronic components 29 can constitute a wiring board circuit (i.e., each functional circuit required for the camera module) together with the wiring in the wiring board 23.

Further, still referring to fig. 9b, in an embodiment of the present application, the inner edge of the movable part main body has a step-shaped notch 43 to avoid the optical lens 10, so that the optical lens 10 can have a larger moving range (i.e. a larger focusing stroke or anti-shake stroke).

Further, fig. 10 shows a schematic top view of the second driving portion in an embodiment of the present application. Referring to fig. 10, in the present embodiment, the second base part 41 may include a base part base 41b and a base part sidewall 41a (refer to fig. 11 in combination) installed to the base part base 41 b. The end surface of the base sidewall 41a may be connected to the edge area of the base 41b, or the base sidewall 41a and the base 41b may be integrally formed. The photosensitive assembly may be fixed to the second movable portion 42, the second base portion 41 and the second movable portion 42 are movably connected by an elastic connection portion (e.g., a spring 47), the second driving portion 40 has four side surfaces, and at least one SMA wire 48 is disposed on at least one side surface of the second driving portion 40. Each SMA wire 48 is located in a gap between the outer side surface of the second movable portion 42 and the inner side surface of the second base portion 41, two ends of each SMA wire 48 are respectively fixed and electrically connected to two fixed ends (for example, a first fixed end a and a second fixed end B, or a third fixed end C and a fourth fixed end D) located in the second base portion 41, the two fixed ends are respectively located in two adjacent corner regions (for example, a first corner and a second corner, or a second corner and a third corner; wherein the first corner and the third corner are opposite corners, and the second fixed end B and the third fixed end C can both be located in the second corner, that is, the second corner is a common corner). The outer side surface of the second movable part 42 has an extending part 44, the extending part 44 is in contact with the waist part 48a of the SMA wire 48, and the extending part 44 presses and bends the SMA wire 48 along the x-axis or y-axis direction at the waist part 480 of the SMA wire 48 under the action of the elasticity of the elastic connecting part (for example, an elastic sheet 47); the second driving part 40 contracts the SMA wire 48 by applying a current to the SMA wire 48 to move the photosensitive chip in the x-axis or y-axis direction. On the other hand, in the present embodiment, the first driving portion is adapted to drive the lens to translate in the x-axis and y-axis directions. The lens and the photosensitive chip are configured to be driven simultaneously and move towards opposite directions; the x axis and the y axis are coordinate axes perpendicular to the optical axis of the camera module, and the x axis and the y axis are perpendicular to each other. Further, in this embodiment, the SMA wires 48 include x-axis drive SMA wires and y-axis drive SMA wires; at least one x-axis drive SMA wire 48a is arranged on at least one side surface 45a of the second drive part perpendicular to the x-axis, and the second drive part enables the x-axis drive SMA wire 48a to contract by supplying current to the x-axis drive SMA wire 48a so as to move the second movable part 42 in the x-axis direction, and further drive the photosensitive chip to move in the x-axis direction. At least one y-axis drive SMA wire 48b is disposed on at least one side 45b of the second drive portion 40 perpendicular to the y-axis, and the second drive portion 40 passes a current through the y-axis drive SMA wire 48b to contract the y-axis drive SMA wire 48b, so as to move the second movable portion 42 in the y-axis direction, and further drive the photosensitive chip to move in the y-axis direction.

In some embodiments of the present application, the extension may be configured as a hook, a pulley, or an arcuate track.

Still referring to fig. 10, in some embodiments of the present application, the second base portion 40 has four corner regions, three of which have the fixed ends, wherein the fixed end of one corner region fixes both the x-axis drive SMA wire 48a and the y-axis drive SMA wire 48 b. The second driving portion 40 has a first side 46a, a second side 46b intersecting the first side 46a, a third side 46c opposite the first side 46a, and a fourth side 46d opposite the second side 46 b; the x-axis drive SMA wires 45a are provided only on the first side 46a and the y-axis drive SMA wires 45b are provided only on the second side 46 b. Further, in an embodiment of the present application, the second driving part may be provided with only one x-axis drive SMA wire and one y-axis drive SMA wire. The number of the SMA wires can be reduced by the design, and the transverse size of the camera module is reduced. The lateral dimension may also be referred to herein as the radial dimension, i.e., the dimension in a direction perpendicular to the optical axis of the camera module.

Further, in some embodiments of the present application, in the second driving portion, a gap between the second base portion inner side surface on the first side and the second movable portion outer side surface (i.e., a gap between the base portion side wall 41a on the first side and the second movable portion 42) is larger than a gap between the second base portion inner side surface on the third side and the second movable portion outer side surface (i.e., a gap between the base portion side wall 41a on the third side and the second movable portion 42). A gap between the second base portion and the second movable portion on the second side is larger than a gap between the second base portion and the second movable portion on the fourth side. Further, fig. 11 shows a schematic cross-sectional view of a camera module in an embodiment of the present application. Referring to fig. 11, in this embodiment, the photosensitive assembly 20 may include a photosensitive chip, a circuit board, and an electronic component 26 mounted on a surface of the circuit board, the photosensitive chip 21 is mounted in a central region of the circuit board 23, the electronic component 26 is located outside the photosensitive chip 21, and the electronic components 26 are located on the first side 46a and/or the second side 46b (i.e., a side on which the x-axis driving SMA wire and/or the y-axis driving SMA wire are/is disposed). Further, fig. 12 is a schematic cross-sectional view illustrating a part of the edge area of the wiring board marked by the camera module of fig. 11. Referring to fig. 12, in the present embodiment, in the photosensitive assembly, the circuit board 23 has four edge regions, which are a first edge region 46a 'located on the first side 46a, a second edge region located on the second side 46b, a third edge region 46 c' located on the third side 46c, and a fourth edge region located on the fourth side 46 d; the width of the third edge region is less than the width of the first edge region; the width of the fourth edge region is less than the width of the first edge region; and the width of the edge area is the distance from the edge of the photosensitive chip to the edge of the circuit board. In this embodiment, the electronic components may be intensively disposed on the first side and the second side of the circuit board, so that the transverse space for disposing the SMA wire is effectively utilized, and the transverse space occupied by the circuit board and the second driving portion on the third side and the fourth side is reduced, thereby helping to reduce the transverse size of the camera module. The lateral dimension may also be referred to herein as the radial dimension, i.e., the dimension in a direction perpendicular to the optical axis of the camera module.

Further, in an embodiment of the present application, in the second driving part, the extension part is at a different height from the fixed end, the height is a position in a z-axis direction, and the z-axis is a coordinate axis perpendicular to the x-axis and the y-axis. In this embodiment, optionally, the extending portion may be higher than the fixed end (the position of the contact point of the extending portion and the SMA wire is higher than the position of the contact point of the fixed end and the SMA wire), so that the force applied by the SMA wire to the extending portion has a downward component (downward along the z-axis), and this downward component cooperates with the spring piece (or called a flexure), so that the movement of the second movable portion in the z-axis direction can be better limited, that is, the anti-shake movement of the second movable portion can be more reliably limited in the xoy plane. In contrast, if the movement of the second movable portion in the z-axis direction is restricted only by the spring piece, the second movable portion may not be prevented from being displaced in the z-axis direction.

Further, in the camera module, the circuit board of the photosensitive assembly generally includes a rigid circuit board main body and a flexible connection belt, one end of the flexible connection belt is connected to the circuit board main body, and the other end of the flexible connection belt is connected to and conducts the main board or other components of the electronic device through the connector. In the prior art, the flexible connecting band of the photosensitive assembly is usually led out from the side of the circuit board main body, and the flexible connecting band is approximately parallel to the surface of the circuit board column. In this arrangement, the flexible connection belt may generate a large resistance to the movement of the circuit board main body, which may increase the force required to drive the circuit board main body to move, resulting in insufficient anti-shake compensation stroke and reduced response speed. Also, the resistance caused by the connection belt is irregular, which makes it difficult for the second driving portion to compensate for the resistance, possibly causing a decrease in accuracy of the anti-shake compensation. Therefore, the present embodiment provides a suspended circuit board as the circuit board of the photosensitive component adapted to the second driving portion, which will help to overcome the above-mentioned drawbacks caused by the connection tape.

Fig. 13 is a perspective view illustrating an assembled second driving unit and photosensitive assembly according to an embodiment of the present disclosure. FIG. 14 illustrates an exploded view of the second drive portion and the photosensitive assembly in one embodiment of the present application. Fig. 15 is a perspective view of a photosensitive assembly and a suspension board used therein according to an embodiment of the present application. Referring to fig. 13, 14 and 15, in the camera module according to the embodiment, the photosensitive element 20 is connected to the second movable portion 42 of the second driving portion 40, so that the circuit board main body 71 can move in the xoy plane under the driving of the second movable portion 42. The circuit board 23 of the present embodiment is designed as a suspended structure. Specifically, the circuit board 23 includes a rigid circuit board main body 71 and a flexible connection tape 72, the connection tape 72 may include a third connection tape 72a and a fourth connection tape 72b, and the third connection tape 72a and the fourth connection tape 72b may be respectively led out from two opposite side surfaces (for convenience of description, the two opposite side surfaces may be referred to as a first side surface 74a and a second side surface 74b) of the circuit board main body 71 and bent upward. The bent third connection band 72a and the bent fourth connection band 72b may form a hanging portion 75, respectively. The suspending portion 75 may be connected with the base portion of the second driving portion 40 (or the first driving portion 30) to form a suspending structure. The suspension structure allows the base portion to suspend the circuit board main body 71 and the components mounted on the surface thereof (i.e., suspend the photosensitive assembly 20) by the bent portion 73 of the flexible connection tape 72. Specifically, in one example, the suspension portion 75 may have a through hole (suspension hole 75a), and the second base portion 41 of the second driving portion 40 may have a corresponding hook 75b, and the hook 75b hooks the through hole of the suspension portion 75 to connect the suspension portion 75. In the prior art, the connecting band and the circuit board main body are generally in the same plane, and the deflection of the connecting band relative to the circuit board main body on the same plane can generate larger resistance. In the present embodiment, the connecting position of the connecting band 72 and the circuit board main body 71 is provided with a bending portion 73 formed by bending upward, and at this time, the resistance generated by the connecting band 72 relative to the circuit board main body 71 in the xoy plane (which can be regarded as a horizontal plane) is relatively small.

Further, in an embodiment of the present application, the third connection tape 72a and the fourth connection tape 72b may extend along the periphery of the circuit board main body 71 and the photosensitive assembly 20, so that the connection tape 72 surrounds the photosensitive assembly on at least three sides. And, the third connection strap 72a and the fourth connection strap 72b are connected to each other and electrically conducted. The photosensitive assembly 20 has a first side 74a and a second side 74b that are aligned with the circuit board main body 71. The first side 74a and the second side 74b are oppositely disposed (i.e., mutually intersected), and the third side 74c of the photosensitive member 20 is intersected with both the first side 74a and the second side 74 b. The connecting band 72 may surround the first side 74a, the second side 74b and the third side 74c of the photosensitive assembly 20. The third connecting belt 72a is led out from the first side 74a of the circuit board main body 71 and bent upward to form the bent portion 73, then extends along the first side 74a of the photosensitive assembly 20, and is bent in the horizontal direction at a corner and continues to extend along the third side 74 c. The fourth connecting band 72b is led out from the second side 74b of the circuit board main body 71 and bent upward to form another bent portion 73, and then extends along the second side 74b of the photosensitive assembly 20, and is horizontally bent at a corner and continues to extend along the third side 74 c. The third connecting strap 72a and the fourth connecting strap 72b can be joined and conducted to each other at the third side 74c, thereby forming a complete connecting strap 72. The three connection band sections at the first, second and third side surfaces 74a, 74b and 74c may respectively have at least one suspension portion 75, and each suspension portion 75 has at least one through hole to be connected with the base portion of the second driving portion 40 (or the first driving portion 30). In this embodiment, the suspending portion 75 can suspend the circuit board main body 71 through the bending portions 73 located at two opposite sides of the circuit board main body 71, so that when the circuit board main body 71 is driven by the second driving portion 40 to move, the bending portions 73 and the connecting band 72 can be bent and deformed, and the moving stroke of the circuit board main body 71 is satisfied.

Further, in one embodiment of the present application, the suspending portions 73 of the three connecting band sections located at the first side surface 74a, the second side surface 74b and the third side surface 74c may be each reinforced by a rigid substrate. For example, a rigid substrate may be attached to a partial region of the flexible connection tape to form the suspended portion 73. And other areas of the flexible connecting belt still keep a flexible state so as to be capable of bending and deforming and meet the moving stroke of the circuit board main body 71.

Further, in an embodiment of the present application, the connection band section located on the third side 74c may have a rigid suspension portion 75c, the suspension portion 75c may lead out a fifth connection band 76, and the fifth connection band 76 may be used for connecting a main board of an electronic device (e.g., a mobile phone).

Further, in another embodiment of the present application, the suspension portion may also be connected with an external bracket (not shown in the drawings), which is directly or indirectly fixed with the base portion of the second driving portion. In the present application, the suspension portion may be fixed to the base portion of the second driving portion by another intermediary. The intermediate member may be directly or indirectly fixed to the base portion of the second driving portion. The intermediate has hooks for hooking the suspending part, or the intermediate is adhered to the suspending part. The intermediary member may be an external frame, a base of the first driving unit, or another intermediary member.

Further, in another embodiment of the present application, the suspension portion may not have the through hole. In this embodiment, the suspension portion may be fixed to the base portion of the second driving portion (or to the base portion of the first driving portion or the outer bracket) by bonding. Further, in another embodiment of the present application, the third connecting band and the fourth connecting band may be rigid-flexible boards, wherein the portion forming the suspension portion may be a rigid board, and both the portion connecting the suspension portion and the bent portion formed by bending upward may be a flexible board. Since the suspension portion is directly formed by the hard plate, the suspension portion in this embodiment may not be reinforced by attaching a rigid substrate.

Further, in an embodiment of the present application, the circuit board main body, the third connecting band and the fourth connecting band may be formed by a complete rigid-flex board.

Further, still referring to fig. 13, 14 and 15, in an embodiment of the present application, the circuit board may further have a fixing portion 76a for fixing the fifth connection strap 76, which is designed to prevent the circuit board main body 71, the third connection strap 72a and the fourth connection strap 72b from being affected by external factors.

Further, fig. 16a shows a schematic front view of a suspension board in one embodiment of the present application after deployment; fig. 16b shows a schematic view of the back side of a hanging cord plate after deployment in one embodiment of the present application. Referring to fig. 16a and 16b, in this embodiment, the circuit board 23 may be formed by a rigid-flex board. The sections of the third connecting band 72a and the fourth connecting band 72b on the third side 74c can be snapped together by connectors 78 and 79 (see fig. 15), so that the third connecting band 72a and the fourth connecting band 72b are connected and fixed and further electrically connected. The third connecting band 72a and the fourth connecting band 72b are provided with circuits therein to lead out the circuits in the circuit board main body 71, and further connected to an external circuit through the fifth connecting band 76 and the connector 77 thereof. Since the third connecting band 72a and the fourth connecting band 72b can respectively lead out a part of the circuit through the corresponding bending part 73 formed by bending upwards, the circuit required to be led out by each bending part 73 can be reduced, so that the width of each bending part 73 can be reduced, and the resistance of the flexible connecting band 72 to the movement of the circuit board main body 71 can be further reduced, and the driving force required to be provided by the second driving part 40 can be further reduced. Note that in other embodiments of the present application, the circuit of the circuit board main body may also be led out through only one of the bent portions (for example, the bent portion bent upward of the third connection tape or the bent portion bent upward of the fourth connection tape).

Further, fig. 17a shows a schematic front view of a suspension board in another embodiment of the present application after being unfolded, and fig. 17b shows a schematic back view of the suspension board in one embodiment of the present application after being unfolded. Referring to fig. 17a and 17b, the photosensitive assembly 20 includes a suspension type circuit board, the suspension type circuit board includes a rigid circuit board main body 71 and a flexible connection strip 72, the connection strip 72 is led out from a first side surface 74a and a second side surface 74b of the circuit board main body 71 and is bent upwards to form a bent portion, a top of the bent portion extends along a circumference of the photosensitive assembly 20 in a horizontal direction, so that the connection strip 72 surrounds peripheries of the first side surface 74a, the second side surface 74b and a third side surface 74c of the photosensitive assembly 20, and the connection strips on the first side surface 74a and the second side surface 74b each have at least one suspension portion 75, and the suspension portions 75 are fixed to the second base portion 41 of the second driving portion 40 or fixed to the second base portion 41 through an interposer; the photosensitive assembly 20 has a first side surface 74a and a second side surface 74b corresponding to the positions of the circuit board main body 71, the first side surface 74a and the second side surface 74b are oppositely arranged, and the third side surface 74c intersects with both the first side surface 74a and the second side surface 74 b. The suspending portion 75 has a suspending hole 75a, and the second base portion 41 or the interposer has a hook that hooks the suspending hole 75 a. The rigid substrate is attached to part of the section of the connecting band for reinforcement to form the suspension part (in a deformed embodiment, the suspension circuit board can also be made of a rigid-flex board, wherein the circuit board main body and the suspension part are formed by the rigid board parts of the rigid-flex board, and the bending part and the connecting band section connected among the suspension parts are formed by the flexible board parts of the rigid-flex board). Unlike the previous embodiment, in the present embodiment, the third side surface 74c is not provided with the hanging portion, that is, the hanging portion 75 and the hanging hole 75a are provided only on the first side surface 74a and the second side surface 74 b. Instead, in the present embodiment, the connection band of the third side surface 74c is fixed to the second base portion 41 by a glue material (or fixed to the second base portion 41 by an intermediary). Specifically, in this embodiment, the connection tape may include a third connection tape 72a and a fourth connection tape 72b, where the third connection tape 72a is led out from the first side surface 74a of the circuit board main body 71 and is bent upward to form one bent portion 73, and then extends along the first side surface 74a of the photosensitive assembly 20, and is bent in a horizontal direction at a corner and continues to extend along the third side surface 74 c; the fourth connecting band 72b is led out from the second side surface 74b of the circuit board main body 71 and bent upward to form another bent portion, then extends along the second side surface 74b of the photosensitive assembly 20, and is horizontally bent at a corner and continues to extend along the third side surface 74 c; the third connection band 72a and the fourth connection band 72b are joined to each other at the third side 74c and are conducted to each other (the joining and conduction can be achieved by snap-fitting of a male and female connector or by welding). Further, fig. 18 is an exploded perspective view of a suspension board-based camera module according to an embodiment of the present application. Fig. 19 illustrates a perspective view of a suspension circuit board based camera module with a housing according to one embodiment of the present application. With reference to fig. 17a, 17b, 18 and 19, in this embodiment, the image capturing module further includes a first connecting strip 84 electrically connected to the first driving portion, and the first connecting strip 84 is led out from the top region of the first driving portion, and then bent downward and engaged with and conducted to the third connecting strip 72a or the fourth connecting strip 72b at the third side 74 c. The camera module further comprises a housing 81 and a module base 80, wherein the inner side surface of the housing 81 is provided with a receiving groove 82 for receiving the joint part of the third side surface 74 c; wherein the joint portion is a joint portion 83 where the first connecting band, the third connecting band 72a, and the fourth connecting band 72b are joined to each other; glue is poured into the accommodating groove 82 to fix the first connecting belt, the third connecting belt 72a and the fourth connecting belt 72b to the housing 81. The module base 80 and the housing 81 can be snapped together to enclose the first optical drive assembly 85 and the second optical drive assembly 86 inside the base 80 and the housing 81 (see fig. 18 and 19). Further, the connecting band on the third side 74c is further connected with a fifth connecting band 76, and the fifth connecting band 76 is provided with a connector 77 for external connection; the suspension board may further have a fixing portion 76a for fixing the fifth connection strap 76. The first optical driving assembly 85 includes a first driving portion and an optical lens, and the optical lens is mounted in the first movable portion of the first driving portion. The second optical driving assembly 86 includes a second driving portion and a photosensitive assembly fixed to a second movable portion of the second driving portion.

In assembling, the first driving unit and the optical lens may be assembled into the first optical driving module 85, and the second driving unit and the photosensitive module may be assembled into the second optical driving module 86. Then, the relative position of the optical lens and the photosensitive chip is adjusted by an active calibration process, and the first driving portion (first base portion) and the second driving portion (second base portion) are bonded by glue. Then, the bonded first optical driving component 85 and second optical driving component 86 are assembled in the through hole of the module housing 81 from bottom to top, and then the module base 80 is attached to the module housing 81; finally, glue is poured into the housing receiving groove 82 to fix the first optical driving assembly 85, the second optical driving assembly 86 and the module housing 81. Meanwhile, glue is poured into the accommodating groove 82, and the joint portion of the first connecting strip 84, the third connecting strip 72a, and the fourth connecting strip 72b may be fixed to the module housing 81, the first base portion, or the second base portion.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and are not limited. Although the present invention has been described in detail with reference to the embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (30)

1. The utility model provides an optics anti-shake module of making a video recording which characterized in that includes:

a lens;

a photosensitive assembly having a photosensitive chip;

the first driving part is suitable for mounting the lens and driving the lens to translate in the direction of the x axis or the y axis; and

the second driving part comprises a second base part and a second movable part, the photosensitive assembly is fixed on the second movable part, the second base part and the second movable part are movably connected through an elastic connecting part, the second driving part is provided with four side surfaces, and at least one SMA wire is arranged on at least one side surface of the second driving part;

each SMA wire is positioned in a gap between the second movable part and the second base part, two ends of each SMA wire are respectively fixed and electrically connected to two fixed ends positioned on the second base part, and the two fixed ends are respectively positioned in two adjacent corner areas of the second base part; the above-mentioned

The outer side surface of the second movable part is provided with an extending part, the extending part is in contact with the waist part of the SMA wire, and the extending part presses and bends the SMA wire along the x-axis direction or the y-axis direction at the waist part of the SMA wire under the action of the elasticity of the elastic connecting part; the second driving part enables the SMA wire to contract by electrifying the SMA wire so as to move the photosensitive chip in the direction of the x axis or the y axis; the lens and the photosensitive chip are configured to be driven simultaneously and move towards opposite directions; the x axis and the y axis are coordinate axes perpendicular to the optical axis of the camera module, and the x axis and the y axis are perpendicular to each other.

2. The optical anti-shake camera module according to claim 1, wherein the first driving unit is adapted to drive the lens to translate in the x-axis and y-axis directions;

the SMA wires comprise an x-axis drive SMA wire and a y-axis drive SMA wire;

at least one X-axis drive SMA wire is arranged on at least one side surface of the second drive part, which is perpendicular to the X-axis, and the second drive part enables the X-axis drive SMA wires to contract by introducing current to the X-axis drive SMA wires so as to move the second movable part in the X-axis direction and further drive the photosensitive chip to move in the X-axis direction; and is

At least one y-axis driving SMA wire is arranged on at least one side surface of the second driving part, which is perpendicular to the y axis, and the second driving part enables the y-axis driving SMA wire to contract by supplying current to the y-axis driving SMA wire so as to move the second movable part in the y-axis direction, and further drive the photosensitive chip to move in the y-axis direction.

3. The optical anti-shake camera module according to claim 1, wherein the extension is configured as a hook, a pulley, or an arcuate rail.

4. The optical anti-shake camera module according to claim 1, wherein the second base portion has four corner regions, three of the corner regions having the fixed ends, and wherein the fixed end of one corner region fixes both the x-axis drive SMA wire and the y-axis drive SMA wire.

5. The optical anti-shake camera module according to claim 4, wherein the second driving portion has a first side, a second side intersecting the first side, a third side opposite to the first side, and a fourth side opposite to the second side; the x-axis drive SMA wires are disposed only on the first side and the y-axis drive SMA wires are disposed only on the second side.

6. The optical anti-shake camera module according to claim 5, wherein the second driving section is provided with only one x-axis drive SMA wire and only one y-axis drive SMA wire.

7. The optical anti-shake imaging module according to claim 5, wherein a gap between the second base portion inner surface and the second movable portion outer surface on the first side in the second driving portion is larger than a gap between the second base portion inner surface and the second movable portion outer surface on the third side; the gap between the second base portion inner surface and the second movable portion outer surface on the second side is larger than the gap between the second base portion inner surface and the second movable portion outer surface on the fourth side.

8. The optical anti-shake camera module according to claim 7, wherein the photosensitive assembly further comprises a circuit board and an electronic component mounted on the surface of the circuit board, the photosensitive chip is mounted in a central region of the circuit board, the electronic component is located outside the photosensitive chip, and the electronic component is located on the first side and/or the second side.

9. The optical anti-shake camera module according to claim 8, wherein the photosensitive assembly has four edge regions, namely a first edge region at the first side, a second edge region at the second side, a third edge region at the third side, and a fourth edge region at the fourth side; the width of the third edge region is less than the width of the first edge region; the width of the fourth edge region is less than the width of the first edge region; and the width of the edge area is the distance from the edge of the photosensitive chip to the edge of the circuit board.

10. The optical anti-shake camera module according to claim 1, wherein the extension portion is at a different height from the fixed end, the height being a position in a z-axis direction, the z-axis being a coordinate axis perpendicular to the x-axis and the y-axis.

11. The optical anti-shake imaging module according to claim 1, wherein the first driving unit includes a first base portion and a first movable portion, and the second base portion is fixed to the first base portion.

12. The optical anti-shake imaging module according to claim 11, wherein the first base portion is located at an outer periphery of the first movable portion; the second basic portion includes basic portion lateral wall and base, the bottom surface of basic portion lateral wall with the base is connected, the top surface of basic portion lateral wall with first basic portion is connected.

13. The optical anti-shake camera module according to claim 12, wherein a step-shaped notch is formed in an edge area of a bottom surface of the first base portion, and a sidewall of the base portion can extend upward and extend into the step-shaped notch and is connected to the first base portion.

14. The optical anti-shake imaging module according to claim 11, wherein the second movable portion includes a movable portion body having a flat plate shape and having a light-passing hole at a center thereof; an outer edge region of the bottom surface of the movable portion main body extends downward to form a movable portion side wall.

15. The optical anti-shake camera module according to claim 14, wherein the photosensitive assembly comprises the photosensitive chip, a circuit board, a lens holder and an optical filter; the photosensitive chip is arranged on the upper surface of the circuit board, the lens base is arranged on the upper surface of the circuit board and surrounds the photosensitive chip, and the optical filter is arranged on the lens base;

the bottom surface of the side wall of the movable part is bonded with the upper surface of the circuit board of the photosensitive assembly; an accommodating cavity is formed among the inner side surface of the side wall of the movable part, the bottom surface of the main body of the movable part, the upper surface of the circuit board and the outer side surface of the mirror base, and electronic elements are arranged in the accommodating cavity;

the second driving part has a first side, a second side intersecting the first side, a third side opposite to the first side, and a fourth side opposite to the second side; the x-axis drive SMA wires are disposed only on the first side and the y-axis drive SMA wires are disposed only on the second side; the electronic components are located on the first side and/or the second side.

16. The optical anti-shake imaging module according to claim 14, wherein an edge area of an inner side of the movable part main body has a stepped notch facing an object side to avoid the optical lens.

17. The optical anti-shake imaging module according to claim 1, wherein the second base part is fixed to the first driving part, the second base part includes a base part side wall that surrounds the second movable part, and a gap for accommodating the SMA wire is provided between the base part side wall and the second movable part.

18. The optical anti-shake camera module according to claim 1, wherein the photosensitive component includes a suspension type circuit board, the suspension type circuit board includes a rigid circuit board main body and a flexible connecting strip, the connecting strip is led out from the first side surface and the second side surface of the circuit board main body and is bent upwards to form a bent portion, the top of the bent portion extends along the peripheral edge of the photosensitive component in the horizontal direction, so that the connecting strip surrounds the peripheries of the first side surface, the second side surface and the third side surface of the photosensitive component, and the connecting strips on the first side surface and the second side surface each have at least one suspension portion, and the suspension portions are fixed to the second base portion of the second driving portion or fixed to the second base portion through an intermediary; the photosensitive assembly is provided with a first side face and a second side face, the positions of the first side face and the second side face are consistent with those of the circuit board main body, the first side face and the second side face are oppositely arranged, and the third side face intersects with the first side face and the second side face.

19. The optical anti-shake camera module according to claim 18, wherein the suspension portion has a suspension hole, and the second base portion or the interposer has a hook that hooks the suspension hole.

20. The optical anti-shake camera module according to claim 18, wherein a portion of the connecting strip is reinforced by attaching a rigid substrate to form the suspension portion.

21. The optical anti-shake camera module according to claim 18, wherein the suspension-type circuit board is made of a rigid-flex board, wherein the circuit board main body and the suspension portions are formed by rigid board portions of the rigid-flex board, and the bending portions and the connecting band sections connected between the plurality of suspension portions are formed by flexible board portions of the rigid-flex board.

22. The optical anti-shake camera module according to claim 21, wherein the connecting tape includes a third connecting tape and a fourth connecting tape, the third connecting tape is led out from the first side of the circuit board main body and bent upward to form a bent portion, then extends along the first side of the photosensitive assembly, and is bent in a horizontal direction at a corner and continues to extend along the third side; the fourth connecting band is led out from the second side face of the circuit board main body and is bent upwards to form another bent part, then extends along the second side face of the photosensitive assembly, is horizontally bent at a corner and continues to extend along the third side face; the third connecting band and the fourth connecting band are joined at the third side surface and conducted to each other.

23. The optical image capturing module of claim 22, further comprising a first connecting strip electrically connected to the first driving portion, wherein the first connecting strip is led out from a top area of the first driving portion, and then bent downward to be engaged with and conducted to the third connecting strip or the fourth connecting strip at the third side.

24. The optical anti-shake camera module according to claim 23, further comprising a housing having an inner side surface with a receiving groove for receiving the engaging portion of the third side surface; wherein the joint portion is a joint portion where the first connecting band, the third connecting band, and the fourth connecting band are joined to each other; and glue is poured into the accommodating groove to fix the first connecting belt, the third connecting belt and the fourth connecting belt to the shell.

25. The optical anti-shake camera module according to claim 22, wherein the connecting strip on the third side is further connected to a fifth connecting strip, and the fifth connecting strip has a connector for external connection; the suspension type circuit board is also provided with a fixing part for fixing the fifth connecting band.

26. The optical anti-shake camera module according to claim 25, further comprising a housing having an inner side with a receiving groove for receiving the engagement portion of the third side; wherein the joint portion is a joint portion where the first connecting band, the third connecting band, and the fourth connecting band are joined to each other; and glue is poured into the accommodating groove to fix the first connecting belt, the third connecting belt and the fourth connecting belt to the shell.

27. The optical anti-shake camera module according to claim 1, wherein a lens moving distance b for the first driving module to drive the lens to move and a photosensitive chip moving distance c for the second driving module to drive the photosensitive chip to move are determined according to the detected tilt shake angle a of the camera module; the lens moving distance b, the photosensitive chip moving distance c and the image space focal length f of the camera module meet the following requirements: a is arctan (b/f) + arctan (c/f).

28. The optical anti-shake camera module according to claim 27, wherein the driving structure further comprises a driving logic module for keeping a ratio of the lens moving distance b to the photosensitive chip moving distance c at a preset fixed ratio.

29. The optical anti-shake camera module according to claim 27, wherein the driving structure further comprises a driving logic module having an anti-shake threshold K, the driving logic module is configured to keep the ratio of the lens moving distance b to the photosensitive chip moving distance c at a predetermined fixed ratio when the tilt shake angle a is smaller than or equal to the anti-shake threshold K, and to make the photosensitive chip moving distance c reach the maximum value c of the moving stroke when the tilt shake angle a is larger than the anti-shake threshold K_maxThe lens moving distance b is in accordance with the relation b ═ tan (a/f) -c_maxAnd (4) calculating.

30. The optical anti-shake imaging module according to claim 28 or 29, wherein the preset fixed ratio of the lens moving distance and the photosensitive chip moving distance is set according to the weight of the lens, the driving force of the first driving part, the weight of the photosensitive chip or photosensitive assembly, and the driving force of the second driving part, so that the time for moving the lens and the photosensitive chip to the respective anti-shake target positions is consistent.

Images